Structural properties and RNA-binding activities of two RNA recognition motifs of a mouse neural RNA-binding protein,mouse-Musashi-1

mouse-Musashi-1 (m-Msi-1) is an RNA-binding protein, abundantly expressed in the developing mammalian central nervous system (CNS). m-Msi-1 contains two RNA recognition motifs (RRMs). In this study, we found that the N-terminal RRM of m-Msi-1 (MMA) binds strongly to poly(G) and weakly to poly(U) in a way similar to that of the full-length m-Msi-1 protein characterized previously. The C-terminal RRM of m-Msi-1 (MMB), however, does not bind to RNA. In addition, the circular dichroism (CD) spectra of the two RRMs showed that the α-helical content of MMA is significantly higher than that of MMB, indicating that some differences in the secondary structure may be responsible for the distinct RNA binding properties of MMA and MMB.     

Mice constitutive for sex-limited protein (SLP) expression contain multiple Slp gene sequences

The murine fourth component of complement (C4) and sex-limited protein (Slp) are two closely related serum proteins whose structural genes map to the S region of H-2. Serum C4 levels vary as much as 20-fold between C4 high (C4H) and C4 low (C4L) strains, and Slp expression can be null (SlpO), limited to male mice of a subset of C4H strains (Slp+), or "constitutive" (SlpC), in which female as well as male mice express Slp. In this study, we compare, by genomic Southern blot analysis, the C4 and Slp genes from eight congenic inbred mouse strains representative of three distinct phenotypes: C4H, Slp+ (two strains), C4H, SlpO (two strains), C4H, SlpC (three strains), and C4L, SlpO (one strain). By using cDNA probes that recognize both C4 and Slp genes, and are derived from the extreme 5' and 3' ends of the mRNA as well as internal coding sequences, we find no evidence to suggest that strain-specific variations in the expression of C4 and Slp are due to gross deletions of major portions of the structural genes. In most cases, two distinct C4/Slp genes are detected; hybridization with C4- and Slp-specific probes indicate that one of these is C4 and the other is Slp. The three SlpC strains are exceptional: they carry at least four C4/Slp genes; one of these hybridizes to the C4-specific probe whereas the remaining genes hybridize to the Slp-specific probe. Hence, multiple duplication of a gene containing Slp sequences has occurred in certain strains of mice, and this is accompanied by constitutive expression of the Slp protein.     

Alternatively expressed domains of AU-rich element RNA-binding protein 1 (AUF1) regulate RNA-binding affinity, RNA-induced protein oligomerization, and the local conformation of bound RNA ligands

AU-rich element RNA-binding protein 1 (AUF1) binding to AU-rich elements (AREs) in the 3'-untranslated regions of mRNAs encoding many cytokines and other regulatory proteins modulates mRNA stability, thereby influencing protein expression. AUF1-mRNA association is a dynamic paradigm directed by various cellular signals, but many features of its function remain poorly described. There are four isoforms of AUF1 that result from alternative splicing of exons 2 and 7 from a common pre-mRNA. Preliminary evidence suggests that the different isoforms have varied functional characteristics, but no detailed quantitative analysis of the properties of each isoform has been reported despite their differential expression and regulation. Using purified recombinant forms of each AUF1 protein variant, we used chemical cross-linking and gel filtration chromatography to show that each exists as a dimer in solution. We then defined the association mechanisms of each AUF1 isoform for ARE-containing RNA substrates and quantified relevant binding affinities using electrophoretic mobility shift and fluorescence anisotropy assays. Although all AUF1 isoforms generated oligomeric complexes on ARE substrates by sequential dimer association, sequences encoded by exon 2 inhibited RNA-binding affinity. By contrast, the exon 7-encoded domain enhanced RNA-dependent protein oligomerization, even permitting cooperative RNA-binding activity in some contexts. Finally, fluorescence resonance energy transfer-based assays showed that the different AUF1 isoforms remodel bound RNA substrates into divergent structures as a function of protein:RNA stoichiometry. Together, these data describe isoform-specific characteristics among AUF1 ribonucleoprotein complexes, which likely constitute a mechanistic basis for differential functions and regulation among members of this protein family.     

Cold-inducible RNA-binding protein (CIRP) regulates target mRNA stabilization in the mouse testis

Cold-inducible RNA-binding protein (CIRP) is an RNA-binding protein that is expressed in normal testis and down-regulated after heat stress. Recent studies suggest that CIRP contributes to male fertility problems but the mechanisms are unclear. The purpose of this study was to identify the likely mechanism of CIRP in reproduction. Based on the RNA-Binding Protein Immunoprecipitation-Microarray (Chip) Profiling (RIP-Chip) and biotin pull-down assays, we found that the mRNAs binding with CIRP in testis were mostly associated with translation regulator activity, antioxidant activity, envelope and reproduction, including important mRNAs related to male infertility. We also discovered that (Un)(n ? 2) was the possible core recognition sequence, and the binding mRNAs increased their stabilization. Our results improve our understanding of the mechanism by which heat stress causes male infertility.     

A comparison of the properties and the solution structure for RNA and DNA quadruplexes which contain two GGAGG sequences joined with a tetranucleotide linker

We have determined solution structure of r(GGAGGUUUUGGAGG) (R14) by NMR; the RNA 14-mer forms an intra-strand parallel quadruplex with a G-tetrad and a hexad, in which a G-tetrad core is augmented by association of two A residues. The quadruplex further forms a dimer through stacking interaction between the hexads. In order to obtain insight into the difference between RNA and DNA quadruplexes, we synthesized the corresponding DNA 14-mer, d(GGAGGTTTTGGAGG) (D14), and examined its properties and structure by CD, gel electrophoresis, and NMR. K+ ions increased the thermal stability of both R14 and D14 structures. The binding affinity of K+ ions to R14 was much higher than that to D14. The CD and gel electrophoretic studies suggest that D14 forms a quadruplex entirely different from that of R14 in the presence of K+ ions; two molecules of D14 form a quadruplex with both antiparallel and parallel strand alignments and with diagonal loops at both ends of the stacked G-tetrads. The NMR study also gave results that are consistent with such structure: alternate glycosidic conformation, 5'G(syn)-G(anti)3', and characteristic chemical shift data observed for many quadruplexes containing diagonal TTTT loops.     

The mouse poly(C)-binding protein exists in multiple isoforms and interacts with several RNA-binding proteins.

The murine poly(C)-binding protein (mCBP) was previously shown to belong to the group of K-homology (KH) proteins by virtue of its homology to hnRNP-K. We have isolated cDNA-splice variants of mCBP which differ by two variable regions of 93 bp and/or 39 +/- 3 bp respectively. Both variable regions are located between the second and third KH-domain of mCBP. The characterization of a partial genomic clone enabled us to propose a model for the generation of the second variable region by the use of a putative alternative splice signal. The mCBP mRNA is expressed ubiquitously and the protein is found predominantly in the nucleus with the exception of the nucleoli. We have identified five proteins which interact with mCBP in the yeast two hybrid system: mouse y-box protein 1 (msy-1), y-box-binding protein, hnRNP-L, filamin and splicing factor 9G8. The interaction between mCBP and splicing factor 9G8 was confirmed in vivo. These results suggest a function of mCBP in RNA metabolism.     

Possible function of RNA-binding proteins of eukaryotes: blocking of RNA accessibility for DNA-interacting (regulatory) protein

In the presence of rat liver cytosol the glucocorticoid receptor complexes (GRC) bind very weakly to RNA as compared to DNA, whereas the binding of purified GRC to RNA is only 2-3 time less than to DNA. It is assumed that the RNA-binding proteins present in the cytoplasm selectively prevent the GRC binding to RNA and thus facilitate the GRC binding to nuclear DNA (chromatin). This blocking function may be performed by the RNA-binding proteins with respect to different regulatory DNA-dependent intracellular proteins in vivo. Possible mechanisms of regulation of the genome activity based on changes in RNA-RNA-binding proteins ratio in intact cells and in individual cell compartments are discussed.     

Dynalign: an algorithm for finding the secondary structure common to two RNA sequences

With the rapid increase in the size of the genome sequence database, computational analysis of RNA will become increasingly important in revealing structure-function relationships and potential drug targets. RNA secondary structure prediction for a single sequence is 73 % accurate on average for a large database of known secondary structures. This level of accuracy provides a good starting point for determining a secondary structure either by comparative sequence analysis or by the interpretation of experimental studies. Dynalign is a new computer algorithm that improves the accuracy of structure prediction by combining free energy minimization and comparative sequence analysis to find a low free energy structure common to two sequences without requiring any sequence identity. It uses a dynamic programming construct suggested by Sankoff. Dynalign, however, restricts the maximum distance, M, allowed between aligned nucleotides in the two sequences. This makes the calculation tractable because the complexity is simplified to O(M(3)N(3)), where N is the length of the shorter sequence.The accuracy of Dynalign was tested with sets of 13 tRNAs, seven 5 S rRNAs, and two R2 3' UTR sequences. On average, Dynalign predicted 86.1 % of known base-pairs in the tRNAs, as compared to 59.7 % for free energy minimization alone. For the 5 S rRNAs, the average accuracy improves from 47.8 % to 86.4 %. The secondary structure of the R2 3' UTR from Drosophila takahashii is poorly predicted by standard free energy minimization. With Dynalign, however, the structure predicted in tandem with the sequence from Drosophila melanogaster nearly matches the structure determined by comparative sequence analysis.     

Evidence that all messenger RNA molecules (except histone messenger RNA) contain Poly (A) sequences and that the Poly(A) has a nuclear function

The appearance of newly formed messenger RNA in polyribosomes of HeLa cells Is inhibited by over 85% by 3′deoxyadenosine (Penman, Rosbash &; Penman, 1970) probably due to the failure of normal attachment of poly(A) to heterogeneous nuclear RNA in the presence of this drug (Darnell, Philipson, Wall &; Adesnik, 1971). Results presented here show that the labeled RNA which does reach polysomes in the presence of 3′deoxyadenosine can be characterized as messenger RNA which contains smaller poly(A) segments than normal messenger RNA. The results of the present experiments suggest that all, or almost all, HeLa cell messenger RNA molecules (except for histone messenger RNA) are derived from nuclear RNA molecules which contain poly (A).     

Poly (A) sequences in insect RNA

RNA isolated from the epidermis and fat body of larvae of the insect Calliphora vicina, contains poly (A) sequences, as demonstrated by binding to nitrocellulose filters and to oligo-dT cellulose. The RNA eluted from the oligo-dT cellulose columns was treated with DNAase, pancreatic RNAase and T₁ nuclease. The size of the nuclease resistant polynucleotides was determined by acrylamide gel electrophoresis and by alkaline hydrolysis and measurement of the adenylic acid to adenosine ratio, the former method yielding 120 to 140 the latter 50 to 65 adenylic acid residues.     

The messenger RNA sequences in growing and resting mouse fibroblasts.

The sequences present in messenger RNA in resting and growing 3T6 cells have been examined. First, the abundance and complexity classes of mRNA in growing 3T6 were compared to those in other established cell lines. The overall complexities measured for mRNA from HeLa cells and the three mouse fibroblast lines, 3T6, SV-PY-3T3, and L, are qualitatively similar and correspond to approximately 10,000 sequences. The relative amount of the two major abundance classes and their complexities appear identical in the three mouse fibroblast lines despite their different histories. HeLa cell mRNA is significantly different both in the amount and the complexity of the two major classes. The complexity of the two mRNA classes appears the same in resting and growing 3T6, although there is a small difference in relative amounts. Cross hybridizing cDNA and mRNA from resting and growing cells shows that the majority of mRNA sequences are the same in the two states. However, cross hybridization after the common sequences are removed shows that about 3% of the mRNA in resting cells is not present in the growing state, while the opposite cross shows 3% of the mRNA in growing cells is not present in resting cells. These differences may result from alterations in gene expression which are related to the growth state of the cell.     

Characterization of a trp RNA-binding attenuation protein (TRAP) mutant with tryptophan independent RNA binding activity

TRAP (trp RNA-binding attenuation protein) is an 11 subunit RNA-binding protein that regulates expression of genes involved in tryptophan metabolism (trp) in Bacillus subtilis in response to changes in intracellular tryptophan concentration. When activated by binding up to 11 tryptophan residues, TRAP binds to the mRNAs of several trp genes and down-regulates their expression. Recently, a TRAP mutant was found that binds RNA in the absence of tryptophan. In this mutant protein, Thr30, which is part of the tryptophan-binding site, is replaced with Val (T30V). We have compared the RNA-binding properties of T30V and wild-type (WT) TRAP, as well as of a series of hetero-11-mers containing mixtures of WT and T30V TRAP subunits. The most significant difference between the interaction of T30V and WT TRAP with RNA is that the affinity of T30V TRAP is more dependent on ionic strength. Analysis of the hetero-11-mers allowed us to examine how subunits interact within an 11-mer with regard to binding to tryptophan or RNA. Our data suggest that individual subunits retain properties similar to those observed when they are in homo-11-mers and that individual G/UAG triplets within the RNA can bind to TRAP differently.     

Insights into activation and RNA binding of trp RNA-binding attenuation protein (TRAP) through all-atom simulations

Tryptophan biosynthesis in Bacillus stearothermophilus is regulated by a trp RNA binding attenuation protein (TRAP). It is a ring-shaped 11-mer of identical 74 residue subunits. Tryptophan binding pockets are located between adjacent subunits, and tryptophan binding activates TRAP to bind RNA. Here, we report results from all-atom molecular dynamics simulations of the system, complementing existing extensive experimental studies. We focus on two questions. First, we look at the activation mechanism, of which relatively little is known experimentally. We find that the absence of tryptophan allows larger motions close to the tryptophan binding site, and we see indication of a conformational change in the BC loop. However, complete deactivation seems to occur on much longer time scales than the 40 ns studied here. Second, we study the TRAP-RNA interactions. We look at the relative flexibilities of the different bases in the complex and analyze the hydrogen bonds between the protein and RNA. We also study the role of Lys37, Lys56, and Arg58, which have been experimentally identified as essential for RNA binding. Hydrophobic stacking of Lys37 with the nearby RNA base is confirmed, but we do not see direct hydrogen bonding between RNA and the other two residues, in contrast to the crystal structure. Rather, these residues seem to stabilize the RNA-binding surface, and their positive charge may also play a role in RNA binding. Simulations also indicate that TRAP is able to attract RNA nonspecifically, and the interactions are quantified in more detail using binding energy calculations. The formation of the final binding complex is a very slow process: within the simulation time scale of 40 ns, only two guanine bases become bound (and no others), indicating that the binding initiates at these positions. In general, our results are in good agreement with experimental studies, and provide atomic-scale insights into the processes.     

The multiple RNA-binding domains of the mRNA poly(A)-binding protein have different RNA-binding activities.

The poly(A)-binding protein (PABP) is the major mRNA-binding protein in eukaryotes, and it is essential for viability of the yeast Saccharomyces cerevisiae. The amino acid sequence of the protein indicates that it consists of four ribonucleoprotein consensus sequence-containing RNA-binding domains (RBDs I, II, III, and IV) and a proline-rich auxiliary domain at the carboxyl terminus. We produced different parts of the S. cerevisiae PABP and studied their binding to poly(A) and other ribohomopolymers in vitro. We found that none of the individual RBDs of the protein bind poly(A) specifically or efficiently. Contiguous two-domain combinations were required for efficient RNA binding, and each pairwise combination (I/II, II/III, and III/IV) had a distinct RNA-binding activity. Specific poly(A)-binding activity was found only in the two amino-terminal RBDs (I/II) which, interestingly, are dispensable for viability of yeast cells, whereas the activity that is sufficient to rescue lethality of a PABP-deleted strain is in the carboxyl-terminal RBDs (III/IV). We conclude that the PABP is a multifunctional RNA-binding protein that has at least two distinct and separable activities: RBDs I/II, which most likely function in binding the PABP to mRNA through the poly(A) tail, and RBDs III/IV, which may function through binding either to a different part of the same mRNA molecule or to other RNA(s).